Traction motor

ABSTRACT

In order to prevent bearing currents, particularly in converter-operated traction motors ( 1 ), the housing ( 11 ) is grounded via a grounding capacitor (C ground ).

The invention relates to a traction motor in vehicles with an electric or diesel-electric drive, the traction motor which is mounted in a housing being grounded.

In vehicles of the generic type, the traction motors are fed either directly from a power system or via a converter with electronic power actuating elements. The housings of the traction motors are grounded here via a grounding cable in the vehicle with an electric drive. Owing to the common-mode voltage (zero voltage), brought about in particular by a converter due to the principle involved, in the traction motor and the sudden changes in voltage at the terminals of the traction motor, of capacitive currents and arc discharges occur in the bearings in association with the parasitic capacitances in the traction motor and in the bearings of the traction motor.

Furthermore, operational reverse currents flow from the driver's own vehicle or from other vehicles via the bearings of the traction motor as a function of the selected grounding concept of the vehicle with an electric drive. This also causes damage to the bearings and to the lubricant and thus leads to premature failure of the bearings.

In order to avoid such damage to the bearings, electrically insulated bearings or insulated bearing bushings are used. Using insulated bearings or insulated bearing bushings prevents the classic wave voltages, low-frequency or DC operating currents and in particular capacitive bearing currents and arc discharges in the bearing which are due to the converter are reduced.

The disadvantage here is that the insulated bearings have a very high purchase value and require relatively sensitive installation in the drive so that the bearing insulation is not damaged. This can be confirmed by additionally checking the insulation after installation.

JP 001309505 describes a traction motor which is rigidly or permanently grounded. A capacitor merely reduces the interference currents of the vehicle with an electric drive.

JP 62114401 also has rigid grounding of the traction motor. The interference currents of the vehicle with an electric drive are returned to the source along the shortest path by means of capacitors.

The invention is accordingly based on the object of providing grounding for a traction motor which avoids the abovementioned disadvantages in a simple manner.

The object is achieved by virtue of the fact that the housing of the traction motor is grounded via a capacitor.

As a result, the insulated bearings may be replaced entirely or partially by the significantly more cost-effective, electrically uninsulated bearings, and the protection of the bearings against damage by stray currents is ensured.

The low-frequency or DC operating reverse currents of the driver's own electric vehicle or of other vehicles which otherwise flow back directly via the rigid grounding to the motor are blocked by the capacitor. As a result, these current components do not flow via the bearings of the traction motor, or only do so to a very low degree.

For the high-frequency interference currents which are due to the converter the capacitor constitutes virtually a short-circuit (XC=1/jwC), i.e. the high-frequency currents can flow back on the shortest path in terms of EMC to the source as in the case of the rigid grounding by means of a grounding cable. This avoids capacitive or grounding currents flowing via the bearings.

The dimensioning of the capacitor significantly reduces the voltage across the bearings so that the dielectric strength of the bearing lubrication film is not exceeded, or is exceeded relatively rarely. Here, a capacitive voltage divider acts between the parasitic winding housing capacitance and the capacitance of the capacitor between the housing of the traction motor and the vehicle ground, for example chassis parallel to the air capacitance and the bearing capacitance. If the voltage at the bearings, that is to say the voltage across the capacitor, does not exceed dielectric strength of the lubrication film in the static case of 0.5 V or in the dynamic case of 2 to 10 V, the lubrication film acts as an insulator and thus prevents the capacitive bearing currents and arc discharges.

Circular currents and currents owing to a wave voltage across the bearings of the traction motor may be prevented in conjunction with this inventive capacitive grounding of the traction motor by making only one bearing electrically insulated.

It is advantageous if the capacitive grounding connection between the housing of the traction motor and ground is provided in the converter. That is to say a four-conductor cable is provided between the traction motor and converter, three conductors for supplying power and a cable for low-inductance provision of grounding.

In a further embodiment, the capacitive grounding connection is provided between the housing of the traction motor and the rotational speed sensor of the traction motor. That is to say the capacitor between the housing of the rotational speed sensor and the shielding of the sensor line is connected in or on the rotational speed sensor. The housings of the rotational speed sensor and traction motor are electrically conductively connected to one another here. It is particularly advantageous if the bearing voltage is monitored in each of the specified embodiments, i.e. said voltage is used as a measurement variable for the functional capability of the capacitor. In the case of a fault, the bearing voltage rises, thus giving a signal that unambiguously indicates the relationship with a faulty capacitor.

The invention and further advantageous refinement of the invention according to features of the subclaims are explained in more detail below using schematically illustrated exemplary embodiments in the drawing, in which:

FIG. 1 shows capacitive grounding of the housing of a traction motor directly on the traction motor,

FIG. 2 shows capacitive grounding of the housing of a traction motor via a converter,

FIG. 3 shows capacitive grounding of the housing of a traction motor via a rotational speed sensor, and

FIG. 4 shows capacitive grounding of the housing of a traction motor via shielding of the power cable

FIG. 1 is a basic illustration of a section of a vehicle with an electric drive through a traction motor 1 and a converter 8 via a wheel set shaft 6. The traction motor 1 is attached to a vehicle body by a king journal (not illustrated in more detail). The traction motor 1 drives a motor shaft 3 which in turn rotates the wheel set shaft 6 via a pinion 4 and a large wheel 5. The capacitor according to the invention is then located as a capacitive grounding means C_(ground) between the housing 11 of the traction motor 1 and the vehicle body or chassis 7. The chassis 7 and/or the vehicle body form the vehicle ground which is also embodied as a protective ground. The vehicle ground is connected to the wheel set shaft 6 via an electrical connection 21, for example via a wheel set brush, and thus to the real ground via the drive wheels (not illustrated in more detail) with an electrically conductive connection.

Because of this grounding capacitor C_(ground), the voltage across the bearings 10 can be significantly reduced so that the dielectric strength of the bearing lubrication film is not exceeded, or is only exceeded rarely. The capacitance of this grounding capacitor is 100-900 μF in large traction motors. The grounding capacitor is to be given smaller dimensions in correspondingly smaller traction motors 1.

Here, the capacitive voltage divider acts between the parasitic winding 2, housing capacitor C_(WG) and the capacitance of the capacitor C_(ground) between the housing 11 of the traction motor 1 and vehicle body or chassis 7 parallel to the air capacitance C_(air) and bearing capacitance C_(bearing). If the bearing voltage, that is to say the voltage across the grounding capacitor C_(ground), the dielectric strength of the lubrication film in the static case of U_(bearing)=0.5 V or in the dynamic case of U_(bearing)=2 to 10 V is not exceeded, the lubrication film acts as an insulator and thus prevents the capacitive bearing currents and arc discharges.

In one advantageous embodiment according to FIG. 2, the grounding with the capacitor C_(ground) is preferably drawn into the converter 8 at low inductance. As a result, the mounting on the traction motor 1 can be simplified significantly since the converter 8 has, by its very nature, certain grounding devices to which the grounding capacitor C_(ground) can be connected. The power cable 9 which serves to supply power has, in this case, a further conductor or a shielding with which the grounding potential is conducted from the traction motor 1 into the converter 8.

In a further advantageous refinement according to FIG. 3, the capacitive grounding of the traction motor 1 is implemented by means of a grounding capacitor C_(ground) on or in the rotational speed sensor 12. The housing of the rotational speed sensor 12 is electrically conductively connected to the housing 11 of the traction motor 1 here. The grounding capacitor C_(ground) is connected between the housing of the rotational speed sensor 12 and the shielding 14 of the rotational speed sensor cable 20.

In a further advantageous embodiment according to FIG. 4, the capacitive grounding of the traction motor 1 is implemented by means of a grounding capacitor C_(ground) between the housing 11 of the traction motor 1 and the shielding 15 of the power cable 9. 

1. A traction motor (1) in vehicles with an electric or diesel-electric drive, the traction motor (1) which is mounted in a housing (11) being grounded, characterized in that the traction motor (1) is grounded via at least one grounding capacitor (C_(ground)).
 2. The traction motor (1) as claimed in claim 1, characterized in that the traction motor (1) can be supplied via electronic power actuating elements.
 3. The traction motor (1) as claimed in claim 1 or 2, characterized in that the grounding connection is between the housing (11) of the traction motor (1) and a vehicle ground is made in or on a rotational speed sensor (12).
 4. The traction motor (1) as claimed in claim 1 or 2, characterized in that the grounding connection between the housing (11) of the traction motor (1) and a vehicle ground is made via the shielding (15) of the power cable.
 5. The traction motor (1) as claimed in claim 2, characterized in that the grounding connection between the housing (11) of the traction motor (1) and a vehicle ground is made in the converter.
 6. The traction motor (1) as claimed in claim 5, characterized in that the grounding connection is made via a separate line in the power supply cable (9) or via the cable shielding of the power supply cable (9).
 7. The traction motor (1) as claimed in one of the preceding claims, characterized in that the electrical voltage is monitored at at least one bearing (10) as a measured variable of a functionally capable grounding connection via the grounding capacitor (C_(ground)). 